Disclosed herein is a high efficiency solar module, the high efficiency solar module includes a solar cell panel formed by layering a frame, a glass, a front Ethyl Vinyl Acetate (EVA), a solar cell, a rear EVA, a carbon fiber plate heating element, a back seat, and a carbon coating film in order, and a snow removal device for melting snow piled up on the solar cell panel, and the snow removal device includes a monitoring part for checking whether or not snow is piled up on the solar cell panel through a CCTV monitor, a reverse bias supplier for sending a current of a battery to the solar cell, and a controller for controlling the monitoring part, the battery, and the reverse bias supplier.

Disclosed herein is a high efficiency solar module, the high efficiency solar module includes a solar cell panel formed by layering a frame, a glass, a front Ethyl Vinyl Acetate (EVA), a solar cell, a rear EVA, a carbon fiber plate heating element, a back seat, and a carbon coating film in order, and a snow removal device for melting snow piled up on the solar cell panel, and the snow removal device includes a monitoring part for checking whether or not snow is piled up on the solar cell panel through a CCTV monitor, a reverse bias supplier for sending a current of a battery to the solar cell, and a controller for controlling the monitoring part, the battery, and the reverse bias supplier.

The embodiments are apparatuses, systems and methods of water management and icicle prevention for solar carports, and are designed to catch drips between rows of, and water run-off from, the low side of inclined photovoltaic modules arranged to form the roof of the solar carport or canopy.

The embodiments are apparatuses, systems and methods of water management and icicle prevention for solar carports, and are designed to catch drips between rows of, and water run-off from, the low side of inclined photovoltaic modules arranged to form the roof of the solar carport or canopy.

The embodiments are apparatuses, systems and methods of water management and icicle prevention for solar carports, and are designed to catch drips between rows of, and water run-off from, the low side of inclined photovoltaic modules arranged to form the roof of the solar carport or canopy.

A system and method for heating a surface. The system can be a solar panel system and the surface can be a solar panel. The system includes a heat source and a processor. The processor determines an amount of heating energy for removing an accumulated material from the solar panel to obtain an unobstructed solar panel, determines an amount of energy production of the unobstructed solar panel, and controls the heat source to apply the determined amount of heating energy to the solar panel when the determined amount of energy production is greater than the amount of heating energy.

A system and method for heating a surface. The system can be a solar panel system and the surface can be a solar panel. The system includes a heat source and a processor. The processor determines an amount of heating energy for removing an accumulated material from the solar panel to obtain an unobstructed solar panel, determines an amount of energy production of the unobstructed solar panel, and controls the heat source to apply the determined amount of heating energy to the solar panel when the determined amount of energy production is greater than the amount of heating energy.

A transparent film has an adhesive backing adapted to emanate heat through heating elements incorporated throughout the film. The film is applied to a front surface of a solar panel array to provide the heat necessary to melt snow and ice. The device is provided with temperature sensors, inverters, and a battery to enable the device to self-activate and to accumulate and store electric power. When the accumulated snow and ice have been melted, the device de-activates and the transparent nature permits sunlight to enter and charge the solar cells.

A transparent film has an adhesive backing adapted to emanate heat through heating elements incorporated throughout the film. The film is applied to a front surface of a solar panel array to provide the heat necessary to melt snow and ice. The device is provided with temperature sensors, inverters, and a battery to enable the device to self-activate and to accumulate and store electric power. When the accumulated snow and ice have been melted, the device de-activates and the transparent nature permits sunlight to enter and charge the solar cells.

A light-concentrating, solar system, comprising: a first Fresnel lens (111) provided with at least one tooth face, wherein each tooth face contains at least one Fresnel unit; two reflective faces (112, 113) arranged to enable incident sunlight to converge via the first Fresnel lens (111), and then to irradiate to a first reflective face (112), and at least part of the incident sunlight to be reflected onto a second reflective face (113) by the first reflective face (112); and a photovoltaic panel (114) arranged to enable at least part of the sunlight reflected by the second reflective face (113) to directly irradiate to or be led to irradiate to the photovoltaic panel (114). Since a twice-reflection structure is adopted, on one hand, the system can provide a higher light-concentration ratio; on the other hand, the height of the system can be reduced; and at the same time, a structural design of the system has better flexibility, so that a peripheral design, such as heat dissipation or heat energy utilization, of a photovoltaic panel can be performed more easily.